WO2024062060A1 - System and method for producing green urea - Google Patents

Abstract

The present invention relates to an apparatus for synthesising urea, the apparatus comprising an ammonia source 10 and a urea synthesis unit 20, the ammonia source 10 being connected to the urea synthesis unit 20 via a reactant line 30, characterised in that the device comprises an ammonia gas turbine 40, wherein the ammonia source 10 is connected to the ammonia gas turbine 40 via a fuel line 50, wherein the ammonia gas turbine 40 is connected to the urea synthesis unit 20 via a steam line 60.

Description

Plant and process for the production of green urea

The invention relates to the production of green urea. In particular, the invention relates to a device for synthesizing urea with the features of claim 1.

The production of green chemicals is becoming increasingly important. “Green” refers to chemicals that have been produced sustainably (and therefore climate-neutrally and environmentally friendly), so that no additional carbon dioxide is released into the atmosphere, especially during their production. For example, these can be chemicals that are produced in processes whose energy requirements for production are covered by renewable/regenerative energies (for example by means of electrical energy that is obtained from renewable energies, for example in a photovoltaic system, a wind turbine, a geothermal power plant or a tidal power plant) and in which the educts used for production are not obtained from fossil raw materials. The production of green ammonia is clearly a focus here, as natural gas is currently used almost exclusively to produce ammonia. During this production, carbon dioxide (CO2) is produced as a byproduct. If this carbon dioxide is not used further, it is released into the environment. However, urea plants can use this carbon dioxide together with the ammonia to convert it into urea, which is primarily used as fertilizer. The use of both product streams from the ammonia plant in the urea plant is one reason why these two plants are often firmly connected to each other. This system network also has the advantage that, for example, steam can be exchanged as an energy source between the two systems. The carbon dioxide bound during urea production is ultimately released again when it is used in the field. Since this carbon dioxide comes from the natural gas from ammonia production, the urea produced in this way is not green.

The production of urea from ammonia and CO2 takes place on a large scale worldwide and is known to those skilled in the art. A method is described in US 2018/0208551 A1. From EP 3 725 401 A1 the use of renewable energy for the production of chemicals is known by increasingly using electricity instead of steam, which is usually generated with fossil fuels.

An energy storage system for the production of hydrogen and urea is known from CN 111378980 A.

From US 2019/0152901 A1 a process for producing ammonia and urea from it is known, in which a conventional gas turbine based on natural gas is used as fuel.

Until now, the production of ammonia and its further conversion to urea usually represented a joint system. Nowadays, the production of ammonia is carried out almost exclusively using the Haber-Bosch process. Hydrogen and CO2 are initially produced from natural gas, with the required thermal energy usually also being generated using natural gas. This hydrogen is then converted into ammonia with nitrogen from the air. The Haber-Bosch process produces steam as process waste heat, which can be used not only for ammonia production itself but also for other processes, such as a subsequent urea process. The high steam requirement for the urea process results, on the one hand, from the frequently used steam turbine of the required CCh compressor and, on the other hand, from the need to carry out several thermal separation processes during the synthesis.

By switching ammonia synthesis to a green synthesis route, its process characteristics change fundamentally. The first step in green synthesis is usually the production of hydrogen by electrolysis from renewable energy. Alternatively, ammonia can also be produced directly using electrochemical methods. This means that no more CO2 is produced as a byproduct, which is required as a feedstock for urea synthesis. By becoming independent of the previous raw material natural gas, it is also possible to move ammonia synthesis to regions where renewable energies are readily available. are (for example, sunny desert regions). In this context, there is also discussion about using the ammonia produced in this way as an easily transportable storage medium for renewable energies, even over longer distances. This takes advantage of the fact that ammonia is comparatively easy to liquefy (unlike hydrogen, for example) in order to obtain a liquid energy carrier with a high energy density.

In contrast to ammonia, CO2 cannot be transported as easily over large distances. It is therefore realistic to assume that new urea syntheses will be located in the future near previously little or unused CCh sources, such as a waste incineration plant or a cement production facility. However, these sites may be geographically distant from ammonia syntheses. This creates the challenge that the steam (energy) usually provided from ammonia synthesis is missing for urea production.

But even if a green ammonia synthesis is operated in direct conjunction with a urea synthesis, the lower steam production of this ammonia synthesis is no longer sufficient to cover the energy requirements of the urea synthesis.

The object of the invention is to provide a plant for producing green urea from green ammonia, in which the urea synthesis from the previous plant network is combined with a gray ammonia synthesis (i.e. an ammonia synthesis, the educts of which are provided using carbon-based fuels, in particular using fossil fuels such as Petroleum, natural gas, coal or components of the aforementioned, the starting materials being obtained, for example, in a steam reforming or in an electrolysis with electricity which is generated using these fuels).

This task is solved by a device with the features specified in claim 1. Advantageous further developments result from the subclaims, the following description and the drawings. The device according to the invention is used to synthesize urea. The device has an ammonia source and a urea synthesis unit. The urea synthesis unit is a common urea synthesis unit known to those skilled in the art for producing urea. The urea synthesis unit usually consists of several process steps and apparatus, including a urea reactor. The aim of the invention is precisely not to intervene in the actual process (and thus the system) of the synthesis of urea, but rather to design the connection to the environment in such a way that, according to the current status, the manufacturing process can also be carried out without the connection to, in particular, natural gas-powered ammonia - Synthesis device works. Ammonia source is to be understood broadly in the sense of the invention. The ammonia source may be an ammonia synthesis device. The ammonia source can also be, for example, a storage tank or a connection to an ammonia pipeline. The only important thing is that the ammonia source no longer provides any or only insufficient steam and CO2 for the urea synthesis unit. The ammonia source is connected via an educt line to the urea synthesis unit, in particular to one or more apparatuses of the urea synthesis unit. According to the invention, the device has an ammonia gas turbine. The ammonia source is connected to the ammonia gas turbine via a fuel line. The ammonia gas turbine is connected to the urea synthesis unit via a steam line.

An ammonia gas turbine is a gas turbine that works with ammonia as a fuel gas (fuel). In the ammonia gas turbine, ammonia is burned, producing nitrogen and water and releasing them into the environment. Such an ammonia gas turbine can provide both thermal energy and mechanical energy, which can be used in different ways for the urea synthesis unit. As a gas turbine, the ammonia gas turbine differs structurally and functionally from turbines in which an existing hot gas flow is used to drive additional units such as compressors (such a turbine is known from WO 2020/212926 A1, where in a urea synthesis a turbocharger is used to feed in Carbamate is used, which - driven by liquid ammonia - enables a coupled feed of ammonia and carbamate). In particular, the Ammonia gas turbine can be used to generate a hot gas flow, the kinetic energy of which can be used to drive a compressor and / or a generator, for example to compress a process gas or to generate electrical energy. Therefore, ammonia gas turbines are currently being built for industrial use to enable electricity generation from the green energy source ammonia. For example, from WO 2015/192877 A1 the use of an ammonia gas turbine for generating electricity is known, in which green ammonia is used as fuel gas. The ammonia gas turbine thus provides the energy necessary for the urea process, which no longer comes from gray ammonia synthesis.

In the present case, ammonia is used as fuel gas in the ammonia gas turbine. Therefore, the ammonia source is not only connected to the urea synthesis unit via an educt line, but also to the ammonia gas turbine via a fuel line. The ammonia gas turbine is further connected to the urea synthesis unit via a steam line; This can in particular be implemented in such a way that the waste heat generated in the ammonia gas turbine is used to produce steam in a downstream heat exchanger (the steam can of course also come from a heat exchanger downstream of the actual combustion process), which can be fed to the urea synthesis unit via a steam line, to use the thermal energy of the steam in the urea synthesis unit, for example to heat the reaction mixture to the required temperature.

The use of green ammonia as an energy supplier has the advantage that no renewable energy production has to be available at the location of the device, or does not have to be reliably available. Since the combustion of green ammonia generates CCh-free energy, green energy can be provided for urea synthesis in a simple manner. This combustion of gaseous ammonia can be carried out efficiently in gas turbines, although the space required is much smaller than for other renewable energy suppliers such as a wind farm and/or a photovoltaic system. Due to the use of green produced ammonia both as a feedstock for urea synthesis and for the production of green energy, for example electricity or steam, in combination with the use of carbon dioxide from other sources, the urea produced in this way can be described as green in the sense of CO2-neutral.

In a further embodiment of the invention, the ammonia gas turbine is connected via a further steam line to a Haber-Bosch reactor for ammonia synthesis. In particular, the steam generated in the Haber-Bosch process is superheated in the ammonia gas turbine and then fed to the urea reactor. For this purpose, the ammonia gas turbine preferably has a heat exchanger in which the water vapor is further heated with the combustion exhaust gases, in particular from the ammonia combustion. The steam can be used in the urea synthesis unit as a heat transfer medium, for example in just one or more heat exchangers of the urea reactor. The steam therefore only serves as a heat transfer medium.

In a further embodiment of the invention, the ammonia gas turbine is designed to directly drive a CO2 compressor. For example, CO2 is produced in exhaust gas purification or in biogas plants at approximately ambient pressure. For urea synthesis, for example, the CO2 must be compressed to 150 bar. The direct coupling achieves dual use of the ammonia gas turbine, the waste heat is used directly in the process and the mechanical power is used to compress the CO2.

In a further embodiment of the invention, the ammonia gas turbine is connected to a generator in a force-locking manner. The ammonia gas turbine drives the generator so that electricity can be generated by the combustion of ammonia. The generator is electrically connected to the urea synthesis unit. This combination has the advantage that it represents a power source that is independent of the rest of the infrastructure. This is especially true when using green ammonia to produce green electricity, as other renewable energy sources such as solar and electricity can be subject to fluctuations. In a further embodiment of the invention, the generator is electrically connected to the CCh compressor.

If the gas turbine and compressor or generator have different speeds, the power can be transmitted between the two machines via a gearbox.

When ammonia is burned, depending on the operating state, nitrogen oxides can form in the gas turbine, which must be removed in a subsequent exhaust gas treatment. For this purpose, the person skilled in the art is already familiar with processes such as selective catalytic reduction.

In a further embodiment of the invention, the ammonia gas turbine is non-positively connected to the CO2 compressor. In particular, the ammonia gas turbine and the CO2 compressor can be arranged on the same shaft, which may contain a gearbox. In this embodiment, the ammonia gas turbine drives the CO2 compressor directly mechanically, so that energy losses, for example during electricity generation and electrical operation of the CO2 compressor, can be avoided.

A further embodiment of the invention has a thermal splitting device. The thermal splitting device is designed to split ammonia into hydrogen and nitrogen. The thermal cracking device is connected to the ammonia source. As a result, ammonia is supplied to the splitting device. The thermal cracking device is connected to the ammonia gas turbine. Since the combustion process of ammonia itself can be subject to fluctuations, in some variants hydrogen is added to the ammonia gas turbine for more stable combustion. It is helpful for this splitting that there is an equilibrium between nitrogen and hydrogen as well as ammonia, which can be shifted to the elements at low pressure. In a further embodiment of the invention, the device has a hydrogen source. A hydrogen source within the meaning of the invention can be, for example, a hydrogen electrolysis device, a hydrogen tank or the connection to a hydrogen network. The hydrogen source is connected to the ammonia gas turbine via a hydrogen line. This allows a certain amount of hydrogen to be added to the ammonia so that more stable combustion is possible.

In a further embodiment of the invention, the ammonia gas turbine is connected to the thermal splitting device via a heat line. The waste heat from the ammonia gas turbine is therefore used to at least partially break down ammonia back into hydrogen and nitrogen.

The device according to the invention is explained in more detail below with reference to embodiments shown in the drawings.

Fig. 1 first embodiment

Fig. 2 second embodiment

Fig. 3 third embodiment

A first embodiment of the device according to the invention is shown in FIG. The device is preferably located near a suitable CO2 source 80. The CCh source 80 can be, for example, a waste incineration plant, a biogas plant or a direct air capture process. Since the ammonia produced for the production of green urea is not produced from natural gas, an ammonia synthesis device is not the CCh source, as was previously the case. The device also has an ammonia source 10. The ammonia source 10 can theoretically be an ammonia synthesis device. However, the latter only makes sense if there is enough renewable energy at this location to produce green ammonia as well as a suitable CCh source 80 for urea production. However, this cannot be assumed in all cases; rather, it can be expected that this is not the case. This means that ammonia is transferred from the ammonia synthesis device to the consumers, for example the Transported device according to the invention. Therefore, the ammonia source 10 can also be a storage tank or a connection to an ammonia pipeline.

Ammonia is supplied from the ammonia source 10 via an educt line 30 to the urea synthesis unit 20. Likewise, the carbon dioxide from the CO2 source 80 is fed to an apparatus in the urea synthesis unit 20 via a CCh compressor 70, in which the carbon dioxide is brought to the pressure required for urea synthesis. In the urea synthesis unit 20, carbon dioxide and ammonia are converted into urea. The urea leaves the urea synthesis unit 20 as a product and is fed, for example, to a granulation device, optionally previously mixed with other components.

In order to provide the necessary energy, the device has an ammonia gas turbine 40. The ammonia gas turbine 40 is connected to the ammonia source 10 via a fuel line 50. If green produced ammonia is converted in the ammonia gas turbine 40, the energy thus generated is also free of CCh emissions. When ammonia is burned, only nitrogen and water are produced and released into the environment.

The ammonia gas turbine 40 is non-positively connected to the CCh compressor 70, in particular both are arranged on the same shaft, which optionally contains a gear. As a result, the ammonia gas turbine 40 drives the CO2 compressor 70 directly. At the same time, the waste heat generated in the ammonia gas turbine 40 is used to produce steam in a downstream heat exchanger, which is fed to the urea synthesis unit 20 via a steam line 60. The steam can also originate in a heat exchanger downstream of the actual combustion process.

Optionally, as shown here, the ammonia gas turbine 40 can also be connected in a force-locking manner to a generator 90. The electrical energy generated there can be made available to the urea synthesis unit 20 via an electrical connection 100. Fig. 2 shows a second embodiment which, in addition to the first embodiment, has a thermal cracking device 110. The thermal cracking device 110 is fed with the waste heat of the ammonia gas turbine 40 via a heat line 120. Part of the ammonia from the ammonia source 10 is fed to the thermal cracking device 110 and the mixture of ammonia, hydrogen and nitrogen produced is fed to the ammonia gas turbine 40. The additional hydrogen leads to more stable combustion in the ammonia gas turbine 40. Fig. 3 shows a third embodiment which differs from the first embodiment shown in Fig. 1 in that the ammonia gas turbine 40 is only non-positively connected to the generator 90, in particular is arranged on the same shaft. The generator 90 is connected via an electrical connection to the CO2 compressor 70, which is accordingly operated purely electrically. The advantage of this embodiment is the optimal operation of the ammonia gas turbine 40 for the generator 90, so that it is easier to react to a fluctuating power requirement, for example in the urea synthesis unit 20 and independently of the CO2 gas stream to be compressed.

Reference symbols

10 ammonia source

20 urea synthesis unit 30 educt line

40 ammonia gas turbine

50 fuel line

60 steam pipe

70 CCh compressor 80 CCh source

90 generator

100 electrical connection

110 thermal splitting device

120 heat conduction 130 product outlet

140 exhaust

Claims

Patent claims

1. Device for the synthesis of urea, the device having an ammonia source (10) and a urea synthesis unit (20), the ammonia source (10) being connected to the urea synthesis unit (20) via an educt line (30), characterized in that Device has an ammonia gas turbine (40), the ammonia source (10) being connected to the ammonia gas turbine (40) via a fuel line (50), the ammonia gas turbine (40) being connected to the urea synthesis unit (20) via a steam line (60).

2. Device according to claim 1, characterized in that the ammonia gas turbine (40) is designed to drive a CCh compressor (70).

3. Device according to one of the preceding claims, characterized in that the ammonia gas turbine (40) is non-positively connected to a generator (90), the generator (90) being electrically connected to the urea synthesis unit (20).

4. Device according to claim 3, characterized in that the generator (90) is electrically connected to the CO2 compressor (70).

5. Device according to one of the preceding claims, characterized in that the ammonia gas turbine (40) is non-positively connected to the CO2 compressor (70).

6. Device according to one of the preceding claims, characterized in that a thermal splitting device (110), the thermal splitting device (110) being designed to convert ammonia into hydrogen and nitrogen, the thermal splitting device (110) being connected to the ammonia source ( 10), wherein the thermal cracking device (110) is connected to the ammonia gas turbine (40). Device according to claim 6, characterized in that the ammonia gas turbine (40) is connected to the thermal splitting device (110) via a heat line (120).